System and method for providing electronic price feeds for tradeable objects

ABSTRACT

System and methods for a price feed generation are described. According to an example method described herein, upon receiving market information including a plurality of linear prices and order quantities, a reference price level is selected and a price feed message is generated to include the reference price level and the plurality of order quantities. The price feed message is then provided to client terminals.

TECHNICAL FIELD

The present invention is directed towards electronic trading. Morespecifically, the present invention is directed to tools for providingimproved price feeds in an electronic trading environment.

BACKGROUND

Electronic trading is generally based on a host exchange, one or morecomputer networks, and client devices. Subscribing traders are connectedto an exchange's electronic trading platform by way of communicationlinks to facilitate real-time electronic messaging between themselvesand the exchanges. The electronic trading platform includes at least oneelectronic market, which is at the center of the trading system andhandles the matching of bids and offers placed by the traders for thatmarket. The electronic messaging includes market information that isdistributed from the electronic market to the traders via an electronicdata feed. Once the traders receive the market information, it may bedisplayed to them on their trading screens. Upon viewing theinformation, traders can take certain actions including the actions ofsending buy or sell orders to the electronic market, adjusting existingorders, deleting orders, or otherwise managing orders. Traders may alsouse software tools on their client devices to automate these andadditional actions.

Although the types of market information published by an electronicexchange may differ from market to market, there are generally somestandard pieces of information. Market information may include data thatrepresents just the inside market. The inside market is the lowestavailable ask price (best ask) and the highest available bid price (bestbid) in the market for a particular tradeable object at a particularpoint in time. Market information may also include market depth. Marketdepth refers to quantities available at the inside market and may alsorefer to quantities available at other prices away from the insidemarket. In addition to providing order book information, such as orderprice and quantity information, electronic exchanges can offer othertypes of market information such as the open price, settlement price,net change, volume, last traded price, the last traded quantity, andorder fill information.

Electronic exchanges and/or intermediary devices, such as gateways,often struggle to balance the amount and timeliness of marketinformation with the bandwidth limitations and reliability of thenetworks to deliver data intensive, fast response market data feeds. Onone hand, a tremendous amount of market information may be generated byan electronic market to adequately characterize a given market,especially when changes in the market are happening at a rapid rate.Often, traders want to access as much of this information as possible sothat they can make better-informed trades. On the other hand,limitations on the amount of market information passed to the tradersare often inherent in the design of physical networks that connecttraders to the electronic market.

Generally, there are two models how electronic markets deliver marketinformation to client devices. In addition, slight variations of the twomodels are sometimes used.

The first model that is most commonly used to deliver market depth is adelta based model. The delta based model involves sending incrementalupdates every time the inside market or market depth changes in an orderbook. In the delta based data delivery environment, a client terminalinitially receives a snapshot of current market conditions listing eachprice level and quantities pending at the price levels. As changes inthe market are detected, such as when a quantity at a certain pricelevel increases, a market update is sent to the client terminal toindicate the incremental change in the quantity.

Many currently existing networks use multicast to deliver delta basedprice data to client terminals. As known in the art, multicast refers tothe delivery of information to many receivers at the same time in asingle stream. Sending delta-based data over multicast, however,requires implementation of application level reliability to guaranteethat all packets are received at a client terminal. If the clientterminal detects a missing update, such as based on a sequence numberincluded in each received update, the client terminal will re-requestthe missing update to correctly use the information in the next update,thus introducing delays and resulting in processing overhead. Toovercome the reliability problems of networks using multicast, pricedata may be sent via a point-to-point network connection created foreach client terminal. However, the use of point-to-point connections intrading environments that include a large number of client terminals isundesirable because a price server has to send each update separately toeach interested client terminal, thus resulting in an inefficient use ofbandwidth and producing delays at the server.

The second data delivery model that is often used involves sending asnapshot update at pre-programmed intervals, such as time-basedintervals or event-based intervals. A snapshot update is a message thatcontains market information such as an inside market and market depthwith actual prices and quantities listed in relation to each priceincluded in the update. Sending the entire depth snapshot hashistorically been considered unrealistic due to the bandwidthconsiderations and packet size.

It would therefore be beneficial to provide a method and system for animproved data distribution that is readily adaptable to communicatingmarket information in a more dynamic way.

BRIEF DESCRIPTION OF THE DRAWINGS

Example embodiments are described herein with reference to the followingdrawings, in which:

FIG. 1 is a block diagram illustrating an example electronic tradingsystem in which a client terminal and a gateway device are on a localarea network;

FIG. 2 is a block diagram illustrating an example system for delivery ofnew and improved price feeds according to one example embodiment;

FIG. 3 is a block diagram illustrating an example format of a messagethat is used to send price and quantity data according to one exampleembodiment;

FIGS. 4A and 4B illustrate an example one level of market depth and amessage format generated for the example depth;

FIGS. 5A and 5B illustrate an example market depth and a message that isgenerated to convey multiple levels of market depth according to theexample embodiment described herein;

FIGS. 6A and 6B illustrate an example market depth of a non-linearmarket and an example market update message generated for such a market;

FIG. 7 is a block diagram illustrating an alternative message formatthat can be used to send price and quantity data according to oneexample embodiment;

FIG. 8 illustrates an example market depth and message blocks that areused to convey multiple levels of market data using the message blockformat of FIG. 7;

FIG. 9 illustrates another example market depth along with messageblocks that are used to convey the illustrated market data using themessage block format of FIG. 7;

FIG. 10 illustrates an example detailed market depth along with messageblocks that are used to convey the illustrated detailed market depthusing the message block format of FIG. 7;

FIGS. 11A and 11B illustrate an example market depth of a non-linearmarket and an example market update message generated for such a marketusing a delta delivery method using the message format of FIG. 3;

FIG. 12 is a block diagram illustrating an example message that is usedto send trade data to client terminals; and

FIG. 13 is a block diagram illustrating an example message that is usedto send session data to client terminals.

SUMMARY

According to example embodiments described herein, system and methodsare provided for providing market data in an electronic tradingenvironment. To illustrate the present invention and aspects thereof,the following description, including the figures and detaileddescription, provides examples that can be used or readily modified byone of ordinary skill to generate a system or method that benefits fromthe teachings described and claimed herein.

According to one example method, market information comprising aplurality of price levels and a plurality of order quantities arereceived for a tradeable object. Upon receiving market information, adetermination is made if the plurality of price levels are linear. Ifthe plurality of price levels are linear, a reference price level isselected, and a price feed message is generated to include the referenceprice level along with the plurality of order quantities. The price feedmessage is then sent to client terminals. If the plurality of pricelevels include non-linear price levels, a price feed message furtherincludes non-linear price levels. Additionally, the price feed messagemay include a plurality of mapping indicators to indicate market depthlevels for which price levels are included in the price feed message.

Other features of the present invention will become more apparent topersons having ordinary skill in the art to which the present inventionpertains from the following description and claims.

DETAILED DESCRIPTION

The present invention is related to generating and providing new marketdata feeds, or more specifically to a price data feed that, among otherthings, can reduce processing, bandwidth and reliability problems. Thepresent invention is applied in an electronic trading networkenvironment, but could be also applied in other network environments aswell. A trading network environment is one that distributes timesensitive data to receiving computers, such as price data. While thedescription will focus on delivery of prices, the example embodimentsmay be equally applied to delivery of other data. To illustrate aspectsof the present invention, a system and method are illustrated in exampleform using the drawings referred to herein. One of ordinary skill in theart will recognize, however, that such examples may be quickly andreadily adaptable using the teachings described herein. Aspects of thepresent invention are protected by the accompanying claims. Limitationsfrom the patent specification should not be improperly incorporated intothe claims unless explicitly stated or otherwise inherently known.

I. Example Trading System Configuration

FIG. 1 illustrates an example electronic trading system 100 in which theexample embodiments may be employed. The example system 100 comprisestrading stations 102A and 102B that access an electronic exchange 108through a gateway 106. As illustrated in FIG. 1, the trading stations102A-B and the gateway 106 are located within a local LAN 104, althoughother configurations are possible, such as the trading stations 102A-Bcommunicating with the gateway 106 through a remote host in a remotenetwork configuration environment. While not shown, a router could beused to route messages between the gateway 106 and the electronicexchange 108. The electronic exchange 108 includes a computer process(e.g., the central computer) that matches buy and sell orders sent fromthe trading stations 102A-B with orders from other trading stations (notshown). The electronic exchange 108 may list one or more tradeableobjects for trading. While not shown in FIG. 1 for the sake of clarity,the trading system may include other devices that are specific to theclient site like middleware and security measures like firewalls, hubs,security managers, and so on, as understood by persons skilled in theart.

Regardless of the types of order execution algorithms used, theelectronic exchange 108 provides market information to the subscribingtrading stations 102A-B. Market information includes price data for oneor more tradeable objects. Price data might include the inside market,which is the best bid and the best ask price currently available for atradeable object, the last traded price, and other prices for whichthere is quantity pending in the market. Price data may include otheritems of interest, or include only certain pieces of information. Whilethe example embodiments are described herein as distributing price data,other types of information can be distributed in an electronic tradingenvironment.

The computer employed as the trading stations 102A-B generally can rangefrom a hand-held device, laptop, or personal computer to a largercomputer such as a workstation and multiprocessor. An illustrativepersonal computer may use Pentium™ microprocessors and may operate undera Windows operating system, or yet may use some other microprocessor oroperating system. Generally, the trading stations 102A-B includes amonitor (or any other output device) and an input device, such as akeyboard and/or a two or three-button mouse to support click basedtrading, if so desired. One skilled in the art of computer systems willunderstand that the present example embodiments are not limited to anyparticular class or model of computer employed for the trading stations102A-B and will be able to select an appropriate system.

In one example embodiment, the trading stations 102A-B use software tocreate specialized interactive trading screens on terminals associatedwith them. Trading screens preferably enable traders to, among otherthings, enter and execute orders, obtain market quotes, and monitorpositions. The range and quality of features available to the trader onhis or her trading screen may vary according to the specific softwareapplication being run. In addition to or in place of the interactivetrading screens, a trading station could run automated types of tradingapplications.

The example embodiment may be implemented in relation to any type oftrading screen, therefore, details regarding the trading screen are notnecessary to understand the present invention. However, in oneembodiment, one type of trading screen that can be used is provided by acommercially available trading application referred to as X_TRADER® fromTrading Technologies International, Inc. of Chicago, Ill. X_TRADER® alsoprovides an electronic trading interface, referred to as MD Trader™, inwhich working orders and/or bid and ask quantities are displayed inassociation with a static price axis or scale.

Portions of the X_TRADER® and the MD Trader™-style display are describedin U.S. Pat. No. 6,772,132, entitled “Click Based Trading With IntuitiveGrid Display of Market Depth,” filed on Jun. 9, 2000, U.S. Pat. No.6,938,011, entitled “Click Based Trading with Market Depth Display”filed on Jun. 9, 2000, U.S. Pat. No. 7,127,424 entitled “Click BasedTrading With Intuitive Grid Display of Market Depth and PriceConsolidation,” filed on Oct. 5, 2001, U.S. patent application Ser. No.10/125,894, entitled “Trading Tools For Electronic Trading,” filed onApr. 19, 2002, and U.S. patent application Ser. No. 10/376,417, entitled“A System and Method for Trading and Displaying Market Information in anElectronic Trading Environment,” filed on Feb. 28, 2003, the contents ofeach are incorporated herein by reference. However, it should beunderstood that orders in the system illustrated in FIGS. 1 and 2 couldalso be placed using any other trading application as well.Additionally, the preferred embodiments are not limited to anyparticular product that performs translation, storage, and displayfunction.

The computer employed as the gateway 106 generally can range from apersonal computer to a larger or faster computer. An illustrativegateway computer may use Pentium™ microprocessors and may operate undera Windows (server or workstation) operating system, or yet some othersystem. Generally, the gateway 106 additionally includes a monitor (orany other output device), input device, and access to a database, if sodesired. One skilled in the art of computer systems will also understandthat the present example embodiments are not limited to any particularclass or model of computer(s) employed for the gateway 106 and will beable to select an appropriate system. Additionally, in some instances, agateway, such as gateway 106, may not even be necessary and/or anothertype of network intermediary device may be employed.

It should be noted that computer systems that are employed here as atrading station or a gateway generally includes a central processingunit, a memory (a primary and/or secondary memory unit), an inputinterface for receiving data from a communication network, an inputinterface for receiving input signals from one or more input devices(for example, a keyboard, mouse, etc.), and an output interface forcommunications with an output device (for example, a monitor). A systembus or an equivalent system may provide communications between thesevarious elements.

Memory on either the gateway 106 or the trading station 102 includes acomputer readable medium. The term computer readable medium, as usedherein, refers to any medium that participates in providing instructionsto a processor unit for execution. Such a medium may take many forms,including but not limited to, non-volatile media, and transmissionmedia. Non-volatile media include, for example, optical or magneticdisks, such as storage devices. Volatile media include, for example,dynamic memory, such as main memory or random access memory (“RAM”).Common forms of computer readable media include, for example, floppydisks, flexible disks, hard disks, magnetic tape, punch cards, CD-ROM,any other physical medium, memory chip or cartridge, or any other mediumfrom which a computer can read.

It should also be noted that the trading stations 102A-B generallyexecute application programs resident at the trading stations 102A-Bunder the control of the operating system of the trading station. Also,the gateway 106 executes application programs resident at the gateway106 under the control of the operating system of the gateway 106. Inother embodiments and as understood by a person skilled in the art, thefunction of the application programs at the trading stations 102A-B maybe performed by the gateway 106, and likewise, the function of theapplication programs at the gateway 106 may be performed by the tradingstations 102A-B.

The actual electronic trading system configurations are numerous, and aperson skilled in the art of electronic trading systems would be able toconstruct a suitable network configuration. For the purposes ofillustration, some example configurations are provided to illustratewhere the elements may be physically located and how they might beconnected to form an electronic trading system. These illustrations aremeant to be helpful to the reader, and they are not meant to belimiting. According to one example, the gateway device may be located atthe client site along with the trading station, which is usually remotefrom the matching process at the electronic exchange. According toanother example, the gateway device may be located at the exchange side.As such, the present invention is not limited to any actual networkconfiguration.

According to the illustrated embodiment, the trading stations 102A-B,the gateway 106, and any routers communicate over the LAN 104, and thegateway 106 may communicate with the matching process at the electronicexchange 108 over a T1, T3, ISDN, or some other high speed connection.In another example illustration, the client site may be located on theactual grounds of the electronic exchange (for example, in the buildingof the exchange). According to this instance, the trading station andthe gateway may still communicate over a LAN, but if any routers areused, they may communicate with the matching process at the electronicexchange through another connection means besides a T1, T3, or ISDN. Inyet another example illustration, the gateway may be housed at, or near,its corresponding electronic exchange. According to this instance, thetrading station may communicate with the gateway over a wide areanetwork or through the use of a T1, T3, ISDN, or some other high speedconnection.

While a single exchange is shown in FIG. 1, it is understood that atrader may obtain access and trade at multiple electronic exchanges. Insuch an embodiment, a client terminal could access multiple exchangesthrough multiple gateways, with each gateway designated for a specificexchange. Alternatively, a single gateway may be programmed to handlemore than one electronic exchange.

It could be very valuable to provide a trader with the opportunity totrade tradeable objects listed at different electronic exchanges. Forexample, a trader could view market information from each tradeableobject through one common visual display. As such, price and quantityinformation from the two separate exchanges may be presented together sothat the trader can view both markets simultaneously in the same window.In another example, a trader can spread-trade different tradeableobjects listed at the different electronic exchanges. Regardless, thepresent invention is not so limited.

II. Example System Configuration

FIG. 2 is a block diagram illustrating an example system 200 fordelivery of new and improved price feeds according to one exampleembodiment. The example system 200 includes an exchange 202 thatprovides price data 204 to a price feed server 206. The price feedserver 206 processes the received price data 204 to generate a new andimproved price feed 208 that will be described in greater detail below.The price feed 208 is then provided to a client terminal 210.

While not specifically shown, it should be understood that the pricefeed server 206 may be located at the exchange 202. Alternatively, theprice feed server 206 may be located at a gateway. Furtheralternatively, the price feed server 206 may be a free standing entityin communication with the exchange 202 and a gateway. Additionally,while only a single client terminal is shown for purposes ofillustration, it should be understood that the price feed server 206 maycommunicate the price feed 208 to multiple client terminals viamulticast or via some other communication methods currently known orlater developed.

III. Example Price Data Feed Generation

The existing price delivery methods suffer many limitations, and themost often used delta based market data delivery requires a high levelof network reliability that results in incurring unnecessary memory,bandwidth and processing resource consumption for fast moving markets.The proposed new price feeds, among other benefits, solve theseproblems.

Depth prices of a typical tradeable object are related by a tick sizethat corresponds to the smallest allowed price increment between theconsecutive prices. For fast moving, high volume markets, prices usuallyhave a linear relationship between their relative positions in themarket. In other words, in most cases depth prices are one tick off fromthe prices at the neighboring price levels. For example, a set of bidprices of {50, 40, 30, 20, 10} having a tick size of 10, and a set ofask prices of {60, 70, 80, 90, 100, 110} also having a tick size of 10,have a linear relationship since all prices are at a single tick offset.Aspects of the example price feeds described herein utilize on thislinearity attribute of the price levels by providing a single referenceprice level and a plurality of quantity values, with other pricesderived for each quantity specified in a price update based on therelative position of each price in relation to the reference price.

While markets tend to be linear, sometimes they may experiencenon-linearity, such as when, for example, a set of prices on either abid side or an ask side is {60, 70, 90, 100, 110}. The market in thisexample is considered non-linear because not all price levels are at asingle tick offset, such as the second price level ‘70’ and the thirdprice level ‘90’ are off by 2 ticks. According to the exampleembodiments for a new price feed, in addition to providing a referenceprice level, prices where the non-linearity is introduced will be sentin a price update message. In either the linear or non-linear markets,eliminating the need to send a number of price levels in a price updatemessage results in a highly efficient compressed price feeds while theprocessing of the compressed updates at the client terminals involvesaddition and subtraction operations of a known value.

The examples that follow will illustrate a number of price feed messagesaccording to the example embodiments. The majority of examples thatfollow illustrate a message format for providing an aggregate quantityvalue at each price level. However, it should be understood that morethan one quantity value could be defined in relation to each price levelwhen a system is configured to provide individual quantity valuescorresponding to each order that is pending at a price level. A messageformat for providing detailed quantity values at each price level willbe illustrated as well.

FIG. 3 is a block diagram illustrating an example format of a message300 that is used to send price and aggregate quantity data according toone example embodiment.

The example message 300 includes a number of packet header fields. Thepacket header fields include a version field 302, a block identifierfield 304, a snapshot identifier field 306, a size field 308, a sequencenumber “sqn” field 310, and a filter key field 312. The version field302 defines a protocol version identifier that is used to create themessage 300. The protocol version identifier may be used at clientterminals that receive the message 300 to decode the message using thespecified version of the protocol that was used to create the message.The block identifier field 304 defines whether quantity, price, or otherdata blocks are included in the message. The snapshot identifier field306 defines whether a snapshot data delivery is used in the message. Ifthe snapshot identifier field 306 is not set, different types of marketdelivery could be used as well. While the example embodiments will focuson the snapshot based market data delivery model, it should beunderstood that the message 300 could include additional fields definingother market delivery types, such as a delta delivery model, acombination of snapshot and delta delivery models, or yet some othermodels.

Referring back to the message 300, a size field 308 defines a size ofthe message in bytes. According to one example embodiment, a maximumpacket size could be defined, such as, for example, 1024 bytes. Asequence field 310 identifies a counter value that is incremented eachtime a message is sent to client terminals. The incremented countervalue specified in the message 300 may be used at the client terminalsto detect packet loss. According to one example embodiment, if thepacket loss exceeds a predefined threshold, a client terminal maytransmit a re-send request for a specific update to a price feed server.Finally, a filter key field 312 in the header of the message 300includes a 32-bit cyclic redundancy check (“CRC”) generated based on theconcatenation of an exchange name, a symbol of a tradeable object, aswell as a series name and a series key that uniquely identify a giventradeable object. According to one example embodiment, the filter key isgenerated to form a unique value so that the filter key may be used tofilter unwanted data at client terminals or other network entities.

Next, the message 300 includes a block header with a type field 314, alength field 316, and a number of block specific fields, hereillustrated at 318-340. The type field 314 defines the block typeincluded in the message 300. According to one example embodiment, therecould be many different block types including a security ID thatuniquely identifies a given tradeable object, tick data defining howprices are represented, depth, implied depth, trade data such as lasttraded price/quantity, session data such as a highest/lowest tradedprice, theoretical market, direct market, indicative market, impliedfrom implied market, market prices, and transitional trading states fora given tradeable object, such open, closed, etc. According to oneexample embodiment, different binary identifiers could be used to definethe illustrative data types. For example, “0” through “11” could be usedto represent each of the example block types, with “0” corresponding tothe security ID type, “1” corresponding to the tick block type, and soon. It should be understood that the illustrated types are onlyexamples, and different data types could be provided as well using themethods described herein.

Next, assuming that the block type is set to depth prices, impliedprices, theoretical prices, indicative prices, direct prices, or yetsome other prices that can be calculated based on market data, fields318-340 are used as shown in the message 300. The ‘a size’ field 318defines a number of asks that are sent in the message 300. According toone example embodiment, a maximum number of asks may be defined to limitthe number of ask levels that are provided to a client terminal in themessage 300. In the example provided in FIG. 3, the message 300 includesfive ask levels with ask fields ‘a1-a5’ shown at 320-328. According toone example embodiment, the ask fields 320-328 are a bitmap indicatingwhich ask prices are non-linear. If a bit is set in any of the askfields, the corresponding price is transferred, as will be illustratedin greater detail below using specific examples. If a bit is clear, thenthe corresponding price is assumed to be one tick better/worse than theprevious price level and is not transferred. Rather, a client terminalreceiving the message 300 may use the specified bitmaps to determine aprice level corresponding to each quantity specified in the message 300.Additionally, according to one example embodiment, a bit in the ‘a1’field 320 is preferably set if the ask size is greater than zero.

Similarly to ask related information provided in the message 300, the ‘bsize’ field indicates the number of bids working that are sent in themessage 300, with bid fields shown at 332-340. Similarly to the askfields, the bid fields 332-340 are used to indicate which bid prices arenon-linear. According to one example embodiment, the bid field 332 isset if the ask size is set to “0,” and the bid size is greater than “0.”If “b1” field is clear and the bid size is greater than “0,” the bidprice is one tick worse than the ask price corresponding to “a1.” If abit is set in any of the bid fields, the corresponding price istransferred. Then, if a bit is clear, the corresponding price is assumedto be one tick better/worse than the previous price, and the price isnot transferred.

The message 300 also includes a number of ask quantity blocks, “ask qty1-ask qty 5” shown at 342-350, bid quantity blocks, “bid qty 1-bid qty5” shown at 352-360, ask price blocks, “ask price 1-ask price 5” shownat 362-370, and finally bid price blocks, “bid price 1-bid price 5”shown at 372-380. According to one example embodiment, the number of askquantities that are transferred in the message 300 is equal to the asksize specified in the ‘a size’ field 318, and the number of bid sidequantities reflects the number in the ‘b size’ field 330. While fivequantity blocks are shown for the bid side and the ask side in themessage 300, it should be understood that, depending on the systemconfiguration, a different number of bid and ask levels could betransferred as well.

Now, referring to the ask/bid price blocks, the number of prices thatare transferred is equal to the number of bits set in ‘a1-a5’ and‘b1-b5’ at 320-328 and 332-340. According to one example embodiment, asingle reference price is transferred, and other prices in linearmarkets are not transferred but rather a client terminal determines theprices not provided in an update based on the known linearcharacteristic associated with other prices in a given market. Forexample, the reference price may be set to the best ask or best bidprice. However, it should be understood that the reference price couldbe set to different prices as well. In the example where the best ask isthe reference price and other ask prices are linear, the best ask pricewould be transferred in the ‘ask price 1’ block and no other ask priceswould be transferred in the message 300. According to one exampleembodiment, if there are no prices working in the market, only a blockheader may be sent to client terminals, with the ask and bid size fieldszeroed out to indicate that all quantities and prices are equal to zero,or are not sent.

The embodiments described above for generation and delivery of new datafeeds will be illustrated hereinafter using specific examples. It shouldbe understood that the examples are only illustrations, and differentvariations or modifications of the examples given below are possible aswell.

A. One Level of Depth Example

While multiple levels of depth are typically sent to client terminals,one level of depth may occasionally be sent. According to one exampleembodiment, one level of depth may be sent for indicative, direct, orsecond generation implied prices, as well as theoretical prices, whensuch prices are provided by an exchange. Additionally, one level ofdepth may be provided when a client terminal subscribes to receive onlyinside market data.

FIGS. 4A and 4B illustrate an example one level of depth 400 and amessage format 402 generated for the example depth 400. According to theexample embodiment illustrated in FIG. 4A, the inside market includes abid quantity of ‘89’ at a best bid price level of ‘50’ along with an askquantity of ‘81’ at a best ask price level of ‘60.’ As shown in themessage 402 illustrated in FIG. 4B, ask and bid size fields 404 and 406are both set to ‘1’ to indicate a single bid and ask being sent in themessage 402. Then, since the best ask price is used as a reference pricein the message, the first field in the ask bitmap 408 is set to ‘1,’with other fields in the ask bitmap 408 and a bid bitmap 410 set to ‘0.’Based on the message configuration shown in FIG. 3, the message 402defines the ask quantity of ‘81’ in a field 412, a bid quantity of ‘89’in a field of 414, and a reference ask price level of 60 in a field of416.

B. Five Levels of Depth Example-Linear Market

In most trading environments, multiple market depth levels are providedto client terminals. FIGS. 5A and 5B illustrate an example market dataset 500 and a message 502 that is generated to convey the market dataaccording to the example embodiment described herein. Referring to FIG.5A, the market data 500 includes five ask price levels and five bidprice levels with the corresponding quantities. Since there are fivebids and five asks in the illustrated market data 500, an ask size field504 and a bid size field 506 are both set to ‘5.’ All prices of themarket data 500 are one tick off from each other, with a tick size of‘10,’ thus the market data is linear. Using the example provided abovewith the best ask price being used as a reference price in a messageupdate, and with the linear price characteristics of the market data500, the message 502 illustrates only a single bit set in the firstfield of an ask bitmap 508, with other bits being set to ‘0’ in the askbitmap 508 as well as a bid bitmap 510.

Referring now to block fields of the message 502, the first five blocks512-520 include five ask quantity levels, with a first ask quantityblock 512 listing a quantity that corresponds to the best ask price, asecond ask quantity block 514 listing a quantity at the next ask pricelevel and so on. Then, the next five blocks 522-532 include five bidquantity levels, with the first bid quantity block 522 listing aquantity at the best bid price, a second bid quantity block 524 listinga quantity at the next bid price level and so on. As mentioned earlierand illustrated in the bitmap 508, the best ask price is used as areference price and thus is included in a block 532. Because otherprices share linear characteristics, no other prices are included in themessage 502.

C. Five Levels of Depth Example-Non-Linear Market

As explained earlier, while most active, fast-moving markets are linear,some markets may occasionally experience non-linear characteristics.FIGS. 6A and 6B illustrate an example market data set 600 of anon-linear market and an example market update message 602 generated forsuch a market. In the illustrated market data set 600, ask prices are‘60,’ ‘80,’ and ‘90,’ and bid prices are ‘40,’ ‘30,’ and ‘10.’ Noquantities are pending at the remaining prices of ‘70,’ ‘50,’ and ‘20.’Since no quantities are pending at the three price levels, such pricesare not sent according to one example embodiment described herein.Because there are three ask and bid price levels at which there arepending quantities, ask and bid size fields 604 and 606 in the message602 indicate ‘3.’

Now, looking at an ask bitmap 608 of ‘1 1 0 0 0,’ the first bit is setto ‘1’ to indicate that the best ask price will be transferred, here theask price level of ‘60.’ Then, the second bit is set to indicate thatthe second best ask price will be transferred as well, here the askprice of ‘80.’ Since all other bits in the ask bitmap are set to ‘0,’ noadditional ask prices are transferred, thus indicating that other pricescorresponding to quantities included in the message 602 are all linear.

Referring now to block fields of the message 602, the first three blocks612-616 include three ask quantity levels, with the first ask quantityblock 612 listing a quantity that corresponds to the best ask price, thesecond ask quantity block 614 listing a quantity at the next ask pricelevel, here at the price level of ‘80,’ and the third ask quantity block616 listing a quantity at the next ask price level of ‘90.’ Then, thenext three blocks 618-622 include three bid quantity levelscorresponding to the bid price levels of ‘40,’ ‘30,’ and ‘10,’respectively. Finally, based on the bitmaps explained above, in additionto the reference price set to the best ask price that is transferred ina block 624, a non-linear ask price is provided in a block 626, alongwith two non-linear bid price levels in blocks 628 and 630.

D. Alternative Message Format

FIG. 7 is a block diagram illustrating an alternative message blockformat 700 according to another example embodiment. According to theembodiment illustrated in FIG. 7, bids and asks are specified indifferent message blocks; however, the blocks can be combined into asingle message. For example, an example message may include a bid depthblock, an ask depth block, an implied bid depth block, an implied askdepth block, etc., examples of which will be described in greater detailbelow.

Referring to FIG. 7, the message 700 includes a header with a type field702, a length field 704, a size field 706, and a bitmap field 708.Similarly to the messages illustrated above, the type field 702 is ablock identifier that defines a type of data specified in the messageblock 700. Example message block types include a direct market bid/askdepth, a direct market ask depth, an implied market bid depth, animplied market ask depth, a detailed bid depth, a detailed ask depth, alast traded price/quantity, etc. The length field 704 defines a lengthof the packet payload in bytes. The depth size field 706 specifies thenumber of market data entries. Then, the bitmap field 708 defineswhether or not a specific price is sent in the message block. In theembodiment illustrated in FIG. 7, each price field is followed by aquantity field defining a quantity that is pending at a price levelcorresponding to the proceeding price field. Similarly to theembodiments described earlier, only a reference price is sent in amessage block and then non-linear prices are defined based on bitsspecified in the bitmap 708. While 8 bits are specified in the bitmap708, it should be understood that fewer or more bits could be used aswell to illustrate fewer or more price levels. In the embodimentillustrated in FIG. 7, every 8 price level/quantity combination pairs,another bitmap is defined, such as a bitmap 742, which corresponds tothe data that is specified following the bitmap 742.

Similarly to the examples given above, when writing and reading themessage block of FIG. 7, the value that is used to infer a price that isnot written is based on the type of data being read/written. For directand implied ask market depth, if a price is not written, the offset thatis applied to the previous value is set to ‘1,’ or yet some other valuedepending on the tick definitions specified for a given tradeableobject. Similarly to the examples given above, the lowest ask price maybe used as a reference price. Then, for direct and implied market biddepth, the offset is set to ‘−1.’ If detailed depth is provided, such aswhen multiple quantity values corresponding to pending orders arespecified for each price level, the offset that is applied in relationto the quantities associated with the same price are set to ‘0,’examples of which will be provided below.

1. First Non-Linear Market Depth Example

FIG. 8 illustrates example message blocks 800 and 802 created for a bidside and an ask side of a market depth 804 having fewer than eight pricelevels on the bid and ask sides. The market depth 804 illustrates anon-linear market on the bid side as well as the ask side. A header ofthe message block 800 includes a bid depth type 806, a length field 808,a number of bids field 810, and a bitmap 812. The length field 808defines the length of the message block 800. It should be understoodthat the length of the message block 800 may depend on whether anycompression is used in relation to all or some data specified in themessage block 800. The bitmap 812 defines price levels that are sent inthe message 800. As shown in the bitmap 812, the best bid of ‘100’ istransferred since the first bit is set to ‘1.’ Then, the next two bidprices are not transferred since they are linear, and the next price of‘60’ with a pending quantity is non-linear and thus is transferred. Thefollowing price of ‘50’ is linear and thus ‘0’ is specified in thebitmap 812.

Now, referring to the message block fields, a first pair of fields 814and 816 define the best bid price of ‘100’ along with the best bidquantity of ‘25.’ Then, since the next two price levels are linear,block fields 818 and 820 define a quantity of 32 and a quantity of 64 atthe two linear price levels. The next block fields 822 and 824 define anon-linear price level of ‘60’ along with a pending quantity of ‘95.’Finally, since the last price level is linear, the last block field 826defines a quantity of ‘48’ pending at the next linear price level of‘50.’

The message block 802 is used to define an ask depth as shown in a typefield 828. The length of the message block 802 is not specified as shownat 830 since the length of the message block 802 may vary depending onwhether any compression is used. A size field defines 4 price/quantitylevels that are provided in the message block 802, and a bitmap 834illustrates which prices are specified in block fields of the messageblock 802. As shown in the bitmap 834, the best ask price is used as areference price level and is sent in a block field 836, and anadditional non-linear price is specified in relation to the third bit,and as shown in a block field 842. All other block fields 838, 840, 844,and 846 define quantity values at each respective price levelcorresponding to the block fields.

2. Second Non-Linear Market Depth Example

FIG. 9 illustrates example message blocks 900 and 912 created for a bidside and an ask side of a market depth 904 having more than eight pricelevels on the bid and ask side of the market. The bid message block 900is used to transfer 10 depth levels, as shown at 902, and has twobitmaps 904 and 906, with the first bitmap defining which of the firsteight bid price levels are transferred, and the second bitmap definingwhether any of the additional prices are transferred. As shown in thefirst bitmap 904, the best bid price level is transferred since thefirst bit is set to ‘1.’ Then, since the remaining seven price levelsare linear, all other bits in the bitmap 904 are set to ‘0.’ The blockfields shown at 908 include the best bid price of ‘170,’ with all otherfields defining quantities at the eight price levels. Then, the bitmap906 defines whether any of the two additional bid price levels aretransferred. Since the last two bid price levels are linear, onlyquantities corresponding to the price levels are transferred in blockfields 910.

Now, referring to the ask message block 912, there are 11 ask pricelevels that are transferred in the block 912, as defined at 914. Thereare two price levels transferred in relation to the first eight pricelevels, the best ask price and the seventh ask price corresponding to anon-linear price. Thus, the first bitmap 916 includes the first andseventh bits set to ‘1’ The block fields shown at 918 define thetransferred prices along with quantities using the format describedabove. Then, since the last two ask prices are linear, no bits are setto ‘1’ in a bitmap 920, and the quantities corresponding to the linearprices are sent in block fields shown at 922.

3. Individual Order Quantities at Price Levels Example

FIG. 10 illustrates example message block formats that are used toprovide detailed depth at each price level. More specifically, asexplained above, rather than providing a single aggregate quantity ateach price level, multiple quantity values could be specified for eachprice if there is more than one order pending at the price level. FIG.10 illustrates an example market depth 1000 along with two messageblocks 1002 and 1004 that are used to represent the bid side and the askside of the market depth 1000, respectively.

The bid message block 1002 includes header fields that were describedabove, with a size field 1006 set to ‘6’ since six values are providedin the message 1002. The format of the message 1008 follows the oneillustrated in FIG. 7, where a quantity value is specified in a messageblock field directly after a field that is used to define a price atwhich the quantity is pending. Thus, because there is more than onefield that is used to define quantity values for each price level, abitmap 1008 is used to specify which block fields list price levels. Inthe bitmap 1008, the first bit is set to indicate that the best bidprice is transferred in a price field 1010. Then, according to thestandard message block configuration, the price field 1010 is followedby a quantity field 1012 defining the first quantity value of an orderpending at the price best bid price. Then, because the next two fieldsare used to represent quantities at the same price level rather than adifferent price, the next two bits in the bitmap 1008 are not set, andthe quantities are defined in fields 1014 and 1016. Then, since the nextfield 1018 is used to define the next price value of ‘205,’ the fourthbit is set in the bitmap 1008. The three message fields 1020-1024 arethen used to represent quantities corresponding to individual orderspending at the price level of ‘205.’

The ask message block 1004 is generated using the same method describedin relation to the bid message block 1002. Since there are more thaneight values that are represented in the message block 1004, two bitmapsare used to indicate which message fields are used to transfer prices.

IV. Compression

In the examples provided above, each quantity and price value specifiedin the messages is sent in a binary format. According to one exampleembodiment, a standard number of bytes, such as 4 bytes, is used torepresent each value even if the value could be represented using asmaller number of bytes. Such an embodiment results in the data beingsent using more bytes than truly required. This deficiency may beovercome using many different compression schemes that could be appliedto quantity values as well as price values provided in the messages.

According to one example embodiment, integer compression may be used torepresent quantities and prices in the messages described above. Integercompression refers to a compression method where only a minimal numberof bytes is used to represent a given value, with an additional bitmapat either the most significant or least significant bits being used torepresent the length of a data string. For example, in the example givenabove where 4 bytes are used to represent a given value, the first fewbits of the first byte may be used to represent the length of a givendata string. In such an embodiment, if the first bit is set to ‘0,’ itis assumed that a single byte is used to represent a value. Then, if thefirst two bits are ‘1’ and ‘0,’ two bytes are used to represent a value,if the first three bits are ‘1,’ ‘1,’ and ‘0,’ three bytes are used, andfinally if three first bits are set to ‘1,’ fours bytes are used, etc.As mentioned earlier, different methods to represent the number of bytesbeing sent for each value could be used as well.

The integer compression results in a significant reduction of the datasize in each message. For example, referring back to the example inFIGS. 5A and 5B where a message is generated for a non-linear market, 10values corresponding to quantities and prices are provided in themessage. In an environment where 4 bytes are used to represent eachvalue, the size required to represent 10 values in the message is 44bytes. Using the proposed integer compression method, since a singlebyte is sufficient to represent each value in a binary format, only 10bytes would be needed to represent the same 10 values.

The compression scheme described above may be also combined with a deltamethod to further reduce the size of data in each message. FIGS. 1A and1B illustrate an example non-linear market depth 1100 and an examplemessage 1102 generated using a delta method. Similarly to the examplesgiven above, the best ask price ‘12160’ is used as a reference pricelevel. Similarly to the example provided in FIG. 6B, the bid and asksize fields 1104 and 1106 indicate ‘3’ since three bid quantities andthree ask quantities are transferred in the message 1102 as shown inmessage blocks 1112-1122. Then, the ask bitmap shown at 1108 is ‘1 1 0 00,’ and a bid bitmap at 1110 is ‘1 0 1 0 0.’

In the example shown in FIG. 11B, rather than representing all prices atwhich the market is non-linear, a single reference price is specified,here the lowest ask price of ‘12160,’ in an ask price block 1124, andall other non-linear prices are specified using an offset method. Basedon the reference price, the next higher ask price is 2 ticks away fromthe reference price, and thus ‘20’ is specified in a bid price block1126 to indicate an offset difference between the reference price andthe next non-linear price level. Then, because the next ask price islinear, only a quantity corresponding to the next ask price level, andnot the offset value for a price level is specified in the message 1102.Then, as shown in relation to the illustrated depth 1100, the best bidvalue is 2 ticks away from the best ask price, and thus the offset forthe best bid price is specified in a bid price block 1128. Since thenext bid price of ‘12130’ is linear as defined in the bitmap 1110, theprice is not transferred. Then, the next bid price of ‘12110’ isnon-linear and thus an offset value is specified in a block field 1130.While the example illustrated in FIG. 11B shows offset values using theactual price difference, it should be understood that offsets could bedefined using a single digit value specifying a tick level difference.

As explained earlier, the prices and quantities defined in the message1102 may be compressed using the integer compression method or yet someother method. In the embodiment illustrated in FIG. 11B, the value‘12160’ is represented using 2 bytes. If all other price levels were tobe represented using the actual values, each price level would berepresented using 2 bytes, thus, resulting in 8 bytes representing fourprice levels. However, since only one reference price is specified usingthe actual price level value, and three other prices are representedusing offset values, the offset values are small enough so that they canbe represented using a single byte. Thus, using the integer encoding incombination with the delta method of sending non-linear prices, themessage size is reduced by 3 bytes with respect to the illustrated pricelevels. As the number of price levels increase, the savings increase aswell.

While not specifically illustrated in the messages shown above, itshould be understood that quantities in each message could berepresented using a delta method to further reduce the message size whencompression methods are used. Those skilled in the art will understandthat many different variations of the message formats are possible aswell.

V. Various Other Market Data Message Formats

In addition to providing market depth related data, there are other datatypes that are normally provided to client terminals in an electronictrading environment. Some example data types along with example messageswill be described below. It should be understood that compressionmethods described above could also be used in relation to data providedin the messages below.

A. Trade Data

FIG. 12 is a block diagram illustrating an example message 1200 that maybe used to send trade data to client terminals. The message 1200includes a last traded quantity (‘ltq’) field 1202, a last traded price(‘ltp’) field 1204, and a total traded quantity (‘ttq’) field 1206.While not shown, the message 800 may include a block header in additionto the illustrated fields.

B. Session Data

FIG. 13 is a block diagram illustrating an example message 1300 that maybe used to send session data to client terminals. The message 1300 maybe sent to notify clients of updates to session prices and otherinformation. Similarly to the message illustrated in FIG. 12, themessage 1300 includes a block header. Message fields illustrated in FIG.13 include five price related fields 1302-1310 that define a sessionhigh price, a session low price, a session open price, a session closeprice, and a session settlement price, respectively. Then, field 1312defines a current status of a tradeable object, and field 1314 defines asession identifier, such as a 32-bit identifier created to identify thecurrent trading session.

While a few additional messages have been illustrated, it should beunderstood that many different messages could be used to conveyadditional market related data.

Although the example programs, processes and methods have been describedand illustrated in detail, it is clearly understood that the same is byway of illustration and example only and is not to be taken by way oflimitation. Since numerous modifications and changes will readily occurto those skilled in the art, it is not desired to limit the invention tothe exact construction and operation shown and described, andaccordingly, all suitable modifications and equivalents may be resortedto, falling within the scope of the invention.

According to one embodiment, the example system takes the form of acomputer program product that is stored on a computer readable storagemedium and is executed by a suitable instruction execution system in thecomputer-based device. The term computer readable medium, as usedherein, refers to any medium that participates in providing instructionsto processor for execution. Such a medium may take many forms, includingbut not limited to, non-volatile media, volatile media, and transmissionmedia. Nonvolatile media includes, for example, optical or magneticdisks, such as storage device. Volatile media includes dynamic memory,such as main memory or RAM (random access memory). Common forms ofcomputer-readable media include, for example, a floppy disk, a flexibledisk, hard disk, magnetic tape, or any other magnetic medium, a CD-ROM,any other optical medium, punch cards, paper tape, any other physicalmedium with patterns of holes, a RAM, a PROM, and EPROM, a FLASH-EPROM,and any other memory chip or cartridge, or any other medium from which acomputer can read.

According to an alternative embodiment, a hardware embodiment might takea variety of different forms. A hardware embodiment may be implementedas an integrated circuit with custom gate arrays or an applicationspecific integrated circuit (“ASIC”). A hardware embodiment may also beimplemented with discrete hardware components and circuitry. Inparticular, it is understood that the logic structures and method stepdescribed in the flow diagrams may be implemented in dedicated hardwaresuch as an ASIC, or as program instructions carried out by amicroprocessor or other computing device. It will be apparent to thoseof ordinary skill in the art that the methods described above may beembodied in a computer program product that includes one or morecomputer readable media. For example, a computer readable medium caninclude a readable memory device, such as a hard drive device, a CD-ROM,a DVD-ROM, or a computer diskette, having computer readable program codesegments stored thereon. The computer readable medium can also include acommunications or transmission medium, such as, a bus or a communicationlink, either optical, wired or wireless having program code segmentscarried thereon as digital or analog data signals.

The claims should not be read as limited to the described order orelements unless stated to that effect. Therefore, all embodiments thatcome within the scope and spirit of the following claims and equivalentsthereto are claimed as the invention.

1. A method for providing market data in an electronic trading environment, comprising: receiving market information for a tradeable object being traded at an electronic exchange, the market information comprising a plurality of price levels and a plurality of order quantities, wherein each price level of the plurality of price levels is associated with at least one trade order pending at the electronic exchange to buy or sell an order quantity for the tradeable object; determining by a computer device that the plurality of price levels includes a linear price level and a non-linear price level, wherein the non-linear price level is separated by more than one default tick increment from a preceding price level of the plurality of price levels; generating by the computer device an indicator sequence comprising a plurality of fields to represent the plurality of price levels, wherein each of the plurality of fields provides an indicator that indicates whether the corresponding price level is linear or non-linear; generating by the computer device a price feed message comprising the indicator sequence, the plurality of order quantities, and the non-linear price level, wherein the linear price level is not provided in the price feed message; and sending the price feed message to a receiving terminal.
 2. The method of claim 1, wherein the market information comprises an inside market with a current highest bid price level and a current lowest ask price level, the method further comprising: using the current highest bid price level or the current lowest ask price level as a reference price level, wherein the price feed message further comprises the reference price level.
 3. The method of claim 1, wherein the plurality of order quantities comprises an aggregate quantity of one or more orders at each of the plurality of price levels.
 4. The method of claim 1, wherein the plurality of order quantities comprises one or more individual order quantities at each of the plurality of price levels.
 5. The method of claim 1, further comprising: generating a first indicator sequence for a plurality of bid price levels in the plurality of price levels; and generating a second indicator sequence for a plurality of ask price levels in the plurality of price levels.
 6. The method of claim 1, wherein the indicator sequence comprises a bitmap having a plurality of bit fields, wherein the indicator is a single bit indicator.
 7. The method of claim 1, further comprising: receiving the price feed message at the receiving terminal; and using the indicator sequence at the receiving terminal to map the plurality of order quantities to the plurality of price levels.
 8. The method of claim 1, further comprising: sending the price feed message to a gateway.
 9. The method of claim 1, wherein the plurality of price levels comprises a plurality of direct price levels, and wherein the plurality of order quantities comprises a plurality of direct order quantities.
 10. The method of claim 1, wherein the plurality of price levels comprises a plurality of implied price levels, and the plurality of order quantities comprises a plurality of implied order quantities.
 11. The method of claim 1, further comprising: using a compression algorithm to compress values in the price feed message that represent the plurality of order quantities.
 12. The method of claim 11, wherein the compression algorithm comprises an integer compression algorithm.
 13. The method of claim 11, further comprising: providing at least one byte to represent each of the plurality of order quantities; using at least one bit of a first byte of the at least one byte to represent how many bytes are used to represent each of the plurality of order quantities.
 14. The method of claim 2, further comprising: using a compression algorithm to compress a value of the reference price level.
 15. The method of claim 1, further comprising: defining an offset value for at least one of the plurality of order quantities at one of the plurality of price levels, the offset value defining a change in the at least one order quantity as compared to a quantity at the one of the plurality of price levels provided in a previous price feed message.
 16. The method of claim 1, wherein the price feed message is generated at an electronic exchange.
 17. The method of claim 1, wherein a price level corresponding to the non-linear price level is higher than the preceding price level.
 18. The method of claim 1, wherein a price level corresponding to the non-linear price level is lower than the preceding price level.
 19. A non-transitory computer readable medium having stored therein instructions executable by a processor, wherein the instructions are executable to: receive market information for a tradeable object being traded at an electronic exchange, the market information comprising a plurality of price levels and a plurality of order quantities, wherein each price level of the plurality of price levels is associated with at least one trade order pending at the electronic exchange to buy or sell an order quantity for the tradeable object; determine by a computer device that the plurality of price levels includes a linear price level and a non-linear price level; generate by the computer device an indicator sequence comprising a plurality of fields to represent the plurality of price levels, wherein each of the plurality of fields provides an indicator that indicates whether the corresponding price level is linear or non-linear, wherein the non-linear price level is separated by more than one default tick increment from a preceding price level of the plurality of price levels; generate by the computer device a price feed message comprising the indicator sequence, the plurality of order quantities, and the non-linear price level, wherein the linear price level is not provided in the price feed message; and send the price feed message to a receiving terminal.
 20. The non-transitory computer readable medium of claim 19, wherein the price level corresponding to the non-linear price level is higher than the preceding price level.
 21. The non-transitory computer readable medium of claim 19, wherein the price level corresponding to the non-linear price level is lower than the preceding price level. 